Mounting bracket, mountable light, and methods of installation thereof

ABSTRACT

Disclosed are mounting brackets, mounting bracket assemblies, mountable lights, and methods of installation thereof. In one embodiment, a mounting bracket assembly comprises an obround-shaped wall mount configured to be mounted to a wall and a light mount configured to be coupled to a surface of a light. The wall mount comprises a raised internal ridge extending from a wall-facing side of the wall mount and a rim segment surrounding the raised internal ridge. A clearance space can be formed in between the wall and the rim segment when the wall mount is mounted to the wall. The light mount comprises a curved ledge and an inwardly-projecting brim. At least part of the curved ledge can rest on a top of the wall mount and the inwardly-projecting brim can be positioned within part of the clearance space when the light is mounted to the wall.

TECHNICAL FIELD

The present disclosure relates generally to the field of mechanical wallmounts, and, more specifically, to an improved mounting bracketassembly, mounting brackets, mountable lights, and methods of installingsuch mounts and lights.

BACKGROUND

There are various ways to mount objects such as lights, picture frames,and other relatively lightweight items to a wall. The most popularmethod is to drive one or more straight or curved nails or screws intothe wall and hang the object from such nails or screws. However, objectshung from nails and screws are often unstable and can become easilydislodged or misaligned when inadvertently bumped or through normal userinteractions with the object.

Another prevalent method is to combine such nails or screws with one ormore hooks or hangers. However, such hooks and hangers are prone tobreaking, are unstable, and are often unsightly when a part of the hookor hanger is exposed.

Yet another method is to use specially-designed wall mounting assembliessuch as interlocking Z-mounts, French cleats, or interlocking clipmounts. While these specially-designed mounting assemblies (e.g.,Z-mounts, interlocking mounts, etc.) provide more stability and allow auser to mount an object closer to the wall (i.e., almost flush with thewall), they often require multiple nails or screws to affix the wallmount components to the wall. This can make such mounting assembliesless appealing for renters or short-term occupants of a dwelling who mayshy away from the idea of making multiple holes in the wall to affixsuch wall mount components. In addition, most specially-designed mountassemblies do not allow room for error if one or more mount componentsare misaligned or not level. This can increase the difficulty of usingsuch mounting assemblies since users must often install and uninstallthe mount multiple times before an object is mounted correctly.

Therefore, a solution is needed which addresses the above shortcomingsand disadvantages. Such a solution should not be overly complicated toinstall and allow a user to easily compensate for small errors. Inaddition, such a solution should be cost-effective and easy tomanufacture.

SUMMARY

Disclosed are a mounting bracket assembly, mounting brackets, mountablelights, and methods of installing such mounts and lights. In oneembodiment, a mounting bracket assembly is disclosed comprising a wallmount configured to be mounted to a wall. The wall mount can beobround-shaped and can comprise a raised internal ridge extending from awall-facing side of the wall mount and a rim segment surrounding theraised internal ridge. A clearance space can be formed in between thewall and the rim segment when the wall mount is mounted to the wall.

The mounting bracket assembly can also comprise an object mountconfigured to be coupled to a surface of a mountable object. The objectmount can comprise a curved ledge and an inwardly-projecting brim. Thecurved ledge can be complementary in shape to a top of the wall mount.At least part of the curved ledge can rest on a top of the wall mountand the inwardly-projecting brim can be positioned within part of theclearance space when the mountable object is mounted to the wall.

In some embodiments, the curved ledge can be substantially shaped as anarch. The curved ledge can be part of an upside down U-shaped protrusionextending from an object-facing surface of the object mount. At leastpart of the upside down U-shaped protrusion can be configured to be slidon to the top of the wall mount when the wall mount is mounted to thewall in order to mount the mountable object to the wall via the mountingbracket assembly.

In some embodiments, the upside down U-shaped protrusion can terminateat two protrusion ends. The two protrusion ends can flare laterallyoutward such that a distance separating the two protrusion ends isgreater than a ledge width of the curved ledge. The flared protrusionends can be configured to allow a user to more easily slide the objectmount on to the wall mount and to level (or slightly adjust therotational positioning of) the mountable object when the mountableobject is mounted to the wall via the mounting bracket assembly.

In some embodiments, the upside down U-shaped protrusion can comprise aprotrusion front surface. The protrusion front surface can be configuredto contact the surface of the mountable object when the object mount iscoupled to or otherwise engaged with the mountable object.

In some embodiments, the rim segment can be obround-shaped. At leastpart of the inwardly-projecting brim of the object mount can be shapedas an upside down U.

In some embodiments, the raised internal ridge of the wall mount canhave a ridge height, the rim segment of the wall mount can have a rimheight, and the ridge height can be greater than the rim height.

In some embodiments, the curved ledge of the object mount can have aledge height. The ledge height can be substantially equal to the rimheight of the rim segment.

In some embodiments, the wall mount can have a wall mount length and awall mount width. The wall mount can further comprise a singularmounting hole positioned substantially in a center of the wall mountsuch that the singular mounting hole is positioned substantially at amidpoint along both the wall mount length and the wall mount width. Thewall mount can be mounted to a wall via one mounting screw extendingthrough the singular mounting hole.

In some embodiments, the object mount can comprise two object mountholes positioned laterally outward of the upside down U-shapedprotrusion. The object mount can be coupled to the surface of themountable object by two object mounting screws extending through the twoobject mount holes.

In another embodiment, a method of mounting an object to a wall isdisclosed. The method can comprise mounting a wall mount to the wall.The wall mount can be obround shaped and comprise a raised internalridge extending from a wall-facing side of the wall mount and a rimsegment surrounding the raised internal ridge. A clearance space can beformed in between the wall and the rim segment when the wall mount ismounted to the wall.

The method can further comprise sliding a mountable object comprising anobject mount coupled to a surface of the mountable object on to a top ofthe wall mount to mount the mountable object to the wall. The objectmount can comprise a curved ledge and an inwardly-projecting brim. Thecurved ledge can be complementary in shape to a top of the wall mount.At least part of the curved ledge can rest on the top of the wall mountand the inwardly-projecting brim can be positioned within part of theclearance space when the mountable object is mounted to the wall.

In some embodiments, the step of sliding the mountable object on to thetop of the wall mount can further comprise sliding at least part of anupside down U-shaped protrusion extending from an object-facing surfaceof the object mount on to the top of the wall mount.

In some embodiments, the step of mounting the wall mount to the wall canfurther comprise screwing one mounting screw into the wall through asingular mounting hole defined in the center of the wall mount, whereinthe singular mounting hole is positioned substantially at a midpointalong both a wall mount length and a wall mount width of the wall mount.

The method can further comprise leveling the mountable object byadjusting the mountable object clockwise or counterclockwise when themountable object is mounted to the wall. The upside down U-shapedprotrusion can terminate at two protrusion ends. The two protrusion endscan flare laterally outward such that a distance separating the twoprotrusion ends is greater than a ledge width of the curved ledge. Theflared protrusion ends can be configured to allow a user to more easilyslide the object mount on to the wall mount and to level (or to slightlyrotate) the mountable object when the mountable object is mounted to thewall via the wall mount and the object mount.

In another embodiment, a mountable lighting system can comprise a wallmount configured to be mounted to a wall. The wall mount can beobround-shaped and can comprise a raised internal ridge extending from awall-facing side of the wall mount and a rim segment surrounding theraised internal ridge. A clearance space can be formed in between thewall and the rim segment when the wall mount is mounted to the wall. Themountable lighting system ca further comprise a light having a lightsurface and a light mount coupled to or integrated with the lightsurface.

The light mount can comprise a curved ledge and an inwardly-projectingbrim. The curved ledge can be complementary in shape to a top of thewall mount. At least part of the curved ledge can rest on a top of thewall mount and the inwardly-projecting brim can be positioned withinpart of the clearance space when the light is mounted to the wall. Insome embodiments, the light surface can comprise a depression or divotdefined along the light surface in proximity to the light mount.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A illustrates one embodiment of a mounting bracket assembly.

FIG. 1B illustrates the mounting bracket assembly in an engagedconfiguration.

FIG. 1C illustrates a rear view of the mounting bracket assembly in theengaged configuration.

FIG. 1D illustrates the mounting bracket assembly of FIG. 1C laid flat.

FIG. 2A illustrates a front view of one embodiment of a wall mount.

FIG. 2B illustrates a rear view of the wall mount of FIG. 2A.

FIG. 3A illustrates a front view of one embodiment of an object mount.

FIG. 3B illustrates a rear view of the object mount of FIG. 3A.

FIG. 4 illustrates an example of a clearance space created by a mountedwall mount.

FIG. 5 illustrates an example method of mounting a mountable object orlight using the mounting bracket assembly disclosed herein.

FIG. 6A illustrates an embodiment of a mountable object.

FIG. 6B illustrates another embodiment of a mountable object.

FIG. 6C illustrates yet another embodiment of a mountable object.

FIG. 6D illustrates a further embodiment of a mountable object.

DETAILED DESCRIPTION

FIG. 1A illustrates one embodiment of an improved mounting bracketassembly 100 for mounting objects to a wall or other mountable surface.The mounting bracket assembly 100 can comprise a wall mount 102 and anobject mount 104. The wall mount 102 can be configured to be mounted toa wall. The object mount 104 can be configured to be coupled to asurface of a mountable object 502 (see, for example, FIGS. 5 and 6A-6D)such as a light, a board, a frame, a vase, a container, or a combinationthereof.

The wall mount 102 can be substantially obround-shaped or resemble theshape of a stadium. For example, the wall mount 102 can have asubstantially rectangular middle section or midportion with semicirclesat opposite ends. In some embodiments, the wall mount 102 can bepartially obround such that the wall mount 102 can have a substantiallyrectangular portion and only one semicircle connected to the rectangularportion.

The wall mount 102 can be configured to be mounted upright such that oneof the semicircles (or the semicircle) serves as a top 106 of the wallmount 102. In some embodiments, the wall mount 102 can comprisesubstantially parallel lateral sides 108 along a middle section ormidportion of the wall mount 102. In other embodiments, the sides 108 ofthe wall mount 102 can converge or diverge.

The wall mount 102 can comprise an object-facing side 110 and awall-facing side 130 (see, for example, FIGS. 1C-1D and 2B). In someembodiments, the object-facing side 110 of the wall mount 102 can besubstantially flat or flush. In other embodiments, at least part of theobject-facing side 110 can be concave or sunken. In these and otherembodiments, the contour or geometry of the object-facing side 110 ofthe wall mount 102 can accommodate or be complementary to a surface(e.g., a rear or side surface) of a mountable object 502.

The wall mount 102 can also comprise a raised internal ridge 128extending from a wall-facing side 130 of a wall mount body 132 of thewall mount 102 (see, for example, FIGS. 1C-1D and 2B). The wall mount102 can also comprise a rim segment 134 surrounding the raised internalridge 128 (see, for example, FIGS. 1C-1D and 2B).

In some embodiments, the wall mount 102 can be mounted with only onemounting screw 514 (see, for example, FIG. 5). The one mounting screw514 can extend through a singular mounting hole 112 positionedsubstantially in a center of the wall mount 102.

As will be discussed in more detail in the following sections, aclearance space 400 (see, for example, FIG. 4) can be formed in betweenthe wall and the rim segment 134 when the wall mount 102 is mounted tothe wall.

The object mount 104 can comprise a curved ledge 114 and aninwardly-projecting brim 116. The shape or geometry of the curved ledge114 can be complementary to or accommodate a shape of the top 106 of thewall mount 102.

In some embodiments, the curved ledge 114 can be substantially shaped asan arch.

The curved ledge 114 can be part of an upside down U-shaped protrusion118 extending from an object-facing surface 120 of the object mount 104.For example, the curved ledge 114 can be the top of the upside downU-shaped protrusion 118. The upside down U-shaped protrusion 118 canhave elongate lateral legs as shown in FIGS. 1A-1B and 3A).

In some embodiments, the inwardly-projecting brim 116 of the objectmount 104 can also be shaped as an upside down U. In other embodiments,the inwardly-projecting brim 116 can be complementary to or accommodatea shape of the rim segment 134 of the wall mount 102.

The upside down U-shaped protrusion 118 can terminate at two protrusionends 122. The two protrusion ends 122 can flare laterally outward suchthat a distance separating the two protrusion ends 122 is greater than awidth of the curved ledge 114. The flared protrusion ends 122 can allowa user to more easily slide the object mount 104 on to the wall mount102. The flared protrusion ends 122 can allow a user to level or adjusta positioning/alignment of a mountable object 502 when the mountableobject 502 is mounted to the wall via the mounting bracket assembly 100.

The object mount 104 can also comprise two object mount holes 124positioned laterally outward of the upside down U-shaped protrusion 118.The object mount 104 can be coupled to a surface (e.g., a rear surfaceor side surface) of the mountable object 502 by two screws extendingthrough the two object mount holes 124.

FIG. 1A illustrates the object mount 104 being slid on to the wall mount102 to engage or interlock with the wall mount 102. The object mount 104can be slid on to the wall mount 102 when the wall mount 102 is securelymounted to a wall. As shown in FIG. 1A, at least part of the upside downU-shaped protrusion 118 can be slid on to the top 106 of the wall mount102 to engage or interlock the object mount 104 with the wall mount 102.The flared protrusion ends 122 of the upside down U-shaped protrusion118 can allow a user to more easily slide the object mount 104 on to thewall mount 102.

FIG. 1B illustrates the mounting bracket assembly 100 in an engagedconfiguration 126. At least part of the curved ledge 114 can rest on thetop 106 of the wall mount 102 when the mounting bracket assembly 100 isin the engaged configuration 126. Moreover, the inwardly-projecting brim116 can be positioned within part of the clearance space 400 (see, forexample, FIG. 4) when the object mount 104 is engaged with the mountedwall mount 102. The inwardly-projecting brim 116 can be caught inbetween the wall and the rim segment 134 of the mounted wall mount 102when the mounting bracket assembly 100 is in the engaged configuration126.

As shown in FIG. 1B, the object mount holes 124 of the object mount 104can be positioned vertically above or superior to the singular mountinghole 112 when the mounting bracket assembly 100 is in the engagedconfiguration 126. In addition, the upside down U-shaped protrusion 118can partially surround the obround-shaped wall mount 102, including thesides 108 of the wall mount 102, when the mounting bracket assembly 100is in the engaged configuration 126.

One technical problem faced by the applicant is how to securely hangrelatively lightweight objects to a wall without requiring a user tohammer multiple nails or insert multiple screws into a wall. Onesolution discovered by the applicant and disclosed herein is the uniquemounting bracket assembly 100 comprising a wall mount 102 and objectmount 104 having the geometries and/or dimensions disclosed herein. Theweight of the mountable object 502 is distributed over the rounded top106 of the wall mount 102, which reduces the likelihood that the wallmount 102 will become dislodged from the wall when the mountable object502 is mounted to the via the mounting bracket assembly 100. Moreover,the unique shape or geometries of the wall mount 102 and object mount104 ensure that the mountable object 502 does not tilt or becomemisaligned when mounted to the wall. Moreover, the wall mount 102 isaesthetically pleasing and unobtrusive when mounted to a wall (even whenexposed).

FIG. 1C illustrates a rear view of the mounting bracket assembly 100 inthe engaged configuration 126. FIG. 1C illustrates that the wall mount102 can comprise a raised internal ridge 128 extending from awall-facing side 130 of a wall mount body 132 of the wall mount 102. Thewall mount 102 can also comprise a rim segment 134 surrounding theraised internal ridge 128.

In some embodiments, the raised internal ridge 128 and the rim segment134 can be configured as obround-shaped rings extending orthogonallyfrom the wall mount body 132 of the wall mount 102. As shown in FIG. 1C,the rim segment 134 and the raised internal ridge 128 can be configuredas concentric obround-shaped rings with the raised internal ridge 128positioned radially inward of the rim segment 134.

In other embodiments, at least one of the raised internal ridge 128 andthe rim segment 134 can be substantially rectangular-shaped,oval-shaped, circular-shaped, or a combination thereof. In these andother embodiments, at least one of the raised internal ridge 128 and therim segment 134 can be discontinuous or comprise one or more breaksalong the ridge or segment. In these and other embodiments, at least oneof the raised internal ridge 128 and the rim segment 134 can refer tounconnected parallel raised ridges or segments rather than a continuousring or polygon.

FIG. 1C also illustrates that a wall-facing surface 136 of the objectmount 104 can be substantially flat or flush. In other embodiments, thewall-facing surface 136 of the object mount 104 can comprise one or moreconcave surface portions or depressions.

FIG. 1D illustrates the mounting bracket assembly 100 of FIG. 1C laidflat such that the object-facing side 110 of the wall mount 102 facesdownward. FIG. 1D illustrates that the raised internal ridge 128 of thewall mount can have a ridge height 138.

FIG. 1D also illustrates that the rim segment 134 of the wall mount 102can have a rim height 140. The ridge height 138 can be greater than therim height 140. The height difference between the ridge height 138 andthe rim height 140 can allow for the clearance space 400 to be createdwhen the wall mount 102 is mounted to the wall.

In some embodiments, the ridge height 138 can be between about 4.0 mm toabout 10.0 mm. For example, the ridge height 138 can be about 6.00 mm,about 8.00 mm, or any height dimensions therebetween. In otherembodiments, the ridge height 138 can be less than 4.0 mm (e.g., betweenabout 2.0 mm and 3.0 mm) or greater than 10.0 mm (e.g., between about12.0 mm and 15.0 mm).

The rim height 140 can be between about 2.0 mm to about 8.0 mm. Forexample, the ridge height 138 can be about 4.00 mm, about 6.00 mm, orany height dimensions therebetween. In other embodiments, the ridgeheight 138 can be less than 2.0 mm (e.g., about 1.0 mm) or greater than8.0 mm (e.g., about 10.0 mm).

The wall mount 102 can be configured such that the ratio of the ridgeheight 138 to the rim height 140 can be about 3:2. In other embodiments,the ratio of the ridge height 138 to the rim height 140 can be about 2:1or about 5:3. The rim height 140 and the ridge height 138 can bedifferent dimensions than those disclosed herein as long as these ratiosare maintained.

The curved ledge 114 of the object mount 104 can also have a ledgeheight 142. The curved ledge 114 is obscured in FIG. 1D. The ledgeheight 142 can be substantially equivalent to the rim height 140 of therim segment 134. For example, the ledge height 142 can be between about4.0 mm to about 10.0 mm. For example, the ledge height 142 can be about6.00 mm, about 8.00 mm, or any height dimensions therebetween.

FIGS. 2A-2B illustrate front and rear views, respectively, of oneembodiment of the wall mount 102. The wall mount 102 can have a wallmount length 200 and a wall mount width 202. As shown in FIG. 2A, thesingular mounting hole 112 can be positioned in a center of the wallmount 102 or substantially at a midpoint along both the wall mountlength 200 and the wall mount width 202.

In some embodiments, the wall mount length 200 can be between about 35.0mm to about 100.0 mm. For example, the wall mount length 200 can beabout, 40.0 mm, about 50.0 mm, about 60.0 mm, about 70.0 mm, about 80.0mm, about 90.0 mm, or any length dimensions therebetween. In otherembodiments, the wall mount length 200 can be between about 100.0 mm toabout 200.0 mm in order to mount larger objects.

The wall mount width 202 can be between about 10.0 mm to about 50.0 mm.For example, the wall mount width 202 can be about 20.0 mm, about 25.0mm, about 30.0 mm, about 35.0 mm, about 40.00 mm, or any widthdimensions therebetween. The wall mount width 202 can be the diameter ofthe semicircle portion(s). In other embodiments, the wall mount length200 can be between about 50.0 mm to about 100.0 mm in order to mountlarger objects.

The wall mount 102 can be configured such that the ratio of the wallmount width 202 to the wall mount length 200 can be about 1:2. In otherembodiments, the ratio of the wall mount width 202 to the wall mountlength 200 can be about 1:3 or about 2:5. The wall mount width 202 andthe wall mount length 200 can be different dimensions than thosedisclosed herein as long as these ratios are maintained.

Although one singular mounting hole 112 is shown in FIGS. 2A-2B, it iscontemplated by this disclosure, in alternative embodiments, that thewall mount 102 can comprise multiple mounting holes. For example, themultiple mounting holes can run down the length of the wall mount 102(along a midline of the wall mount 102) or arranged in a patternthroughout the wall mount body 132.

FIG. 2B illustrates that the rim segment 134 and the raised internalridge 128 can be substantially obround-shaped or oval-shaped. The rimsegment 134 and the raised internal ridge 128 can extend orthogonallyfrom the wall mount body 132 of the wall mount 102. As shown in FIG. 2B,the rim segment 134 and the raised internal ridge 128 can be configuredas concentric obround-shaped rings with the raised internal ridge 128positioned radially inward of the rim segment 134.

A few technical problems faced by the applicant is how to design a wallmount 102 that is aesthetically pleasing, easy to install, and leaveslittle or no scuff marks on a wall or mounting surface when mounted andafter the wall mount 102 is removed from the wall or mounting surface.The solution discovered by the applicant and disclosed herein is theunique wall mount 102 having the geometries and/or dimensions previouslydisclosed.

FIGS. 3A-3B illustrate front and rear views, respectively, of oneembodiment of the object mount 104 (e.g., light mount). A front view, inthis context, refers to viewing an object-facing surface 120 of theobject mount 104 and a rear view, in this context, refers to viewing awall-facing surface 136 of the object mount 104.

FIG. 3A illustrates that the object mount 104 can comprise an upsidedown U-shaped protrusion 118 extending orthogonally from an object mountbody 300. The object mount body 300 can be substantially flat.

As shown in FIGS. 3A and 3B, the object mount body 300 can have asubstantially pentagonal profile or shape. In other embodiments, theobject mount body 300 can have a substantially hexagonal or otherpolygonal shape or profile. In further embodiments, the object mountbody 300 can have an oval or obround shape or profile.

The upside down U-shaped protrusion 118 can be positioned radiallyoutward of the inwardly-projecting brim 116. In some embodiments, theinwardly-projecting brim 116 can be part of or integrated with theobject mount body 300. In other embodiments, the inwardly-projectingbrim 116 can be coupled or affixed to the object mount body 300. In someembodiments, at least part of the inwardly-projecting brim 116 can beshaped substantially as an upside down U.

The upside down U-shaped protrusion 118 can have a protrusion frontsurface 302. In some embodiments, the protrusion front surface 302 canbe configured to contact the surface (e.g., a rear surface or sidesurface) of the mountable object 502 when the object mount 104 iscoupled or otherwise affixed to the mountable object 502. When theobject mount 104 is coupled or otherwise affixed to the mountable object502, the upside down U-shaped protrusion 118, the inwardly-projectingbrim 116, and the surface (e.g., the rear surface or side surface) ofthe mountable object create a partially enclosed receiving space for atleast part of the wall mount 102. For example, the top 106 and middleportion of the wall mount 102 can slide into the partially enclosedreceiving space when the user engages the object mount 104 with themounted wall mount 102.

FIGS. 3A and 3B also illustrate that the object mount body 300 can havea void space 304 or cutout defined along a midportion or middle of theobject mount body 300. The void space 304 or cutout can have a shape ordimensions that complement at least part of the shape or dimensions ofthe wall mount 102 or feature(s) thereof. For example, when the wallmount 102 (including the raised internal ridge 128) is substantiallyobround-shaped, the void space 304 or cutout can be at least partiallyobround-shaped. In other embodiments, the void space 304 or cutout canhave a shape or dimensions that are not the same as the shape ordimensions of the wall mount 102 or feature(s) thereof. In theseembodiments, the void space 304 or cutout can have a void width that isgreater than a width of the raised internal ridge 128.

When the wall mount 102 is mounted to the wall or other mountingsurface, the void space 304 or cutout allows part of the object mount104 to slide over or cap on to part of the mounted wall mount 102.

FIG. 3A further illustrates that the upside down U-shaped protrusion 118terminates at two protrusion ends 122. The two protrusion ends 122 canflare laterally outward such that a distance separating the twoprotrusion ends 122 (hereinafter referred to as a protrusion separationwidth 306) is greater than a ledge width 308 of the curved ledge 114 atthe top of the upside down U-shaped protrusion 118. The flaredprotrusion ends 122 are configured to allow a user to more easily slidethe object mount 104 on to the mounted wall mount 102 and to allow auser to level or slightly adjust the rotation of the mountable object502 when the mountable object 502 is mounted to the wall via themounting bracket assembly 100 (see, for example, FIG. 5).

FIG. 3B illustrates that, in some embodiments, the object mount 104 cancomprise two object mount holes 124 positioned laterally outward of theupside down U-shaped protrusion 118. In these embodiments, the objectmount 104 can be coupled to the surface of the mountable object 502 bytwo object mounting screws (not shown) extending through the two objectmount holes 124. When the object mount body 300 has a substantiallypentagonal profile or shape, the object mount holes 124 can bepositioned at non-adjacent corners of the pentagon. Moreover, althoughtwo object mount holes 124 are shown in the figures, it is contemplatedthat the object mount 104 can comprise three, four, or more object mountholes 124 for affixing or otherwise securing the object mount 104 tolarger mountable objects.

Furthermore, although the object mount holes 124 are shown in thefigures, it is contemplated by this disclosure that the object mount 104can be affixed or otherwise secured to the mountable object 502 byadhesives, clips, ties, holders, an interference fit, or a combinationthereof. In other embodiments, the object mount 104 can be affixed orotherwise secured to the mountable object 502 by one or more screws incombination with adhesives, clips, ties, holders, or an interferencefit.

In further embodiments, the object mount 104 can be integrated with themountable object 502 or be a contiguous surface feature of the mountableobject 502. For example, when the mountable object 502 is a light,frame, board, or container, the object mount 104 can be integrated withor be defined on a surface of the light, frame, board, or container.

In some embodiments, at least one of the wall mount 102 and the objectmount 104 can be made in part of a polymeric material, a metallicmaterial, a ceramic, or wood. More specifically, at least one of thewall mount 102 and the object mount 104 can be made in part of a hardthermoplastic such as polycarbonate (PC). In other embodiments, at leastone of the wall mount 102 and the object mount 104 can be made in partof acrylonitrile butadiene styrene (ABS) or polyvinyl chloride (PVC). Infurther embodiments, at least one of the wall mount 102 and the objectmount 104 can be made in part of stainless steel or aluminum.

FIG. 4 illustrates that a clearance space 400 can be formed in betweenthe wall and the rim segment 134 when the wall mount 102 is mounted tothe wall. The clearance space 400 can be a gap or free space separatingthe rim segment 134 from the wall. When the wall mount 102 issubstantially obround-shaped, the clearance space 400 can besubstantially shaped as an obround ring.

The clearance space 400 can have a space depth 402. In some embodiments,the space depth 402 can be between about 1.0 mm to about 2.0 mm. Forexample, the space depth 402 can be about 1.2 mm, about 1.4 mm, about1.6 mm, about 1.8 mm, or any depth dimensions therebetween. In otherembodiments, the space depth 402 can be between about 2.0 mm and 3.0 mm.For example, the space depth 402 can be about 2.2 mm, about 2.4 mm,about 2.6 mm, about 2.8 mm, or any depth dimensions therebetween.

At least part of the inwardly-projecting brim 116 of the object mount104 can be positioned within at least part of the clearance space 400when the object mount 104 is engaged with the mounted wall mount 102.More specifically, at least part of the inwardly-projecting brim 116 ofthe object mount 104 can be caught in between the wall and at least partof the rim segment 134 of the wall mount 102 when the object mount 104is engaged with the mounted wall mount 102.

A user can also remove the mountable object 502 from the wall mount 102(i.e., disengage the object mount 104 from the wall mount 102) bysliding the mountable object 502 off of the wall mount 102 and removingthe inwardly-projecting brim 116 of the object mount 104 from theclearance space 400.

FIG. 5 illustrates a method 500 of mounting a mountable object 502 to awall. The method 500 can comprise mounting a wall mount 102 to the wallin a first step 504. The method 500 can also comprise a second step 506of sliding the mountable object 502 comprising an object mount 104coupled to a surface 508 of the mountable object 502 on to a top 106 ofthe wall mount 102 to mount the mountable object 502 to the wall. Thesurface 508 can be a rear surface or a side surface of the mountableobject 502. The surface 508 can have a depression 510 or divot along thesurface 508. The depression 510 or divot can be positioned or defined inproximity to (e.g., below) the object mount 104 coupled or affixed tothe surface 508 of the mountable object 502. The depression 510 or divotcan allow the object mount 104 to more easily slide on to the wall mount102.

The method 500 can further comprise an optional third step 512 ofleveling the mountable object 502 once the mountable object 502 ismounted to the wall via the mounting bracket assembly 100 by slightlyadjusting the mountable object 502 clockwise or counterclockwise (e.g.,by slightly tilting or adjusting the rotation of the mountable object502 clockwise or counterclockwise).

More specifically, the first step 504 can involve mounting the wallmount 102 to the wall by screwing a singular mounting screw 514 into thewall through a singular mounting hole 112 defined in the center of thewall mount 102. Alternatively, a wall anchor 516 or anchor screw can beinserted into the wall first to distribute the applied force of themounting screw 514 over a larger surface area of the wall or to preventthe weight of the mountable object 502 from pulling the mounting screw514 out of the wall. The wall anchor 516 can be used when the wall mount102 is mounted to drywall, other types of hollow walls, or plasterboard.In these embodiments, the mounting screw 514 can be screwed into thewall anchor 516 rather than directly into the wall.

The second step 506 can involve positioning the mountable object 502such that the object mount 104 affixed or secured to the rear or sidesurface of the mountable object 502 is directly over the top 106 of thewall mount 102 and sliding the object mount 104 on to the top 106 of thewall mount 102.

As previously discussed, the wall mount 102 can be obround-shaped andcan comprise a raised internal ridge 128 extending from the wall-facingside 130 of the wall mount body 132 (see, for example, FIGS. 1C and 1D)of the wall mount 102. The wall mount 102 can also comprise a rimsegment 134 (see, for example, FIGS. 1C and 1D) surrounding the raisedinternal ridge 128. A clearance space 400 (see, for example, FIG. 4) canbe formed in between the wall and the rim segment 134 when the wallmount 102 is mounted to the wall. The object mount 104 can comprise aninwardly-projecting brim 116 and an upside down U-shaped protrusion 118extending from an object-facing surface 120 of the object mount 104. Theupside down U-shaped protrusion 118 can comprise a curved ledge 114.

Sliding the mountable object 502 on to the top 106 of the wall mount 102can further involve sliding at least part of the upside down U-shapedprotrusion on to the top 106 of the wall mount 102. At least part of thecurved ledge 114 can rest on the top of the wall mount 102 and theinwardly-projecting brim 116 can be positioned within the clearancespace 400 or caught in between the wall and the rim segment 134 of thewall mount 102 when the mountable object 502 is mounted to the wall viathe mounting bracket assembly 100.

The third step 512 can involve leveling the mountable object 502 oncethe mountable object 502 is mounted to the wall via the mounting bracketassembly 100 by slightly adjusting, rotating, or tilting the mountableobject 502 clockwise or counterclockwise. The unique design of theobject mount 104 can allow the mountable object 502 to be leveled or tocorrect the alignment of the mountable object 502 even after themountable object 502 is mounted to the wall via the mounting bracketassembly 100.

As previously discussed, the upside down U-shaped protrusion 118 of theobject mount 104 can terminate at two protrusion ends 122. The twoprotrusion ends 122 flare laterally outward such that a distanceseparating the two protrusion ends 122 is greater than a ledge width 308of the curved ledge 114. The flared protrusion ends 122 can allow a userto more easily engage the object mount 104 with the mounted wall mount102. The flared protrusion ends 122 can also allow a user to more easilylevel the mountable object 502 by slightly rotating or tilting themountable object 502 clockwise or counterclockwise after the mountableobject 502 is already mounted to the wall via the mounting bracketassembly 100.

One technical problem faced by the applicant is how to design a mountingbracket assembly 100 where a mountable object 502 having an object mount104 affixed or otherwise secured to the mountable object 502 can beeasily and quickly mounted to a wall via a wall mount 102 and unmountedfrom the wall or wall mount 102. Another technical problem faced by theapplicant is how to design a mounting bracket assembly 100 where thelevel or rotational positioning of the mountable object 502 can beadjusted (e.g., slightly tilted or slightly rotated) after beingmounted. The solution discovered by the applicant is the unique designof the object mount 104 disclosed herein having the flared protrusionends 122 and the wall mount 102 disclosed herein having the previouslydisclosed shape and geometries.

FIGS. 6A-6D illustrate examples of mountable objects 502 that can bemounted to a wall or another mounting surface by the mounting bracketassembly 100. FIGS. 6A and 6B illustrate that the mountable objects 502can be lights or lamps that can be mounted to a wall or another mountingsurface by the mounting bracket assembly 100. As previously discussed,the lights or lamps can each have a rear or side surface comprising adepression or divot (see for example, the depression 510 shown in FIG.5) defined along the rear or side surface. The depression or divot canbe positioned or defined in proximity to the object mount 104 coupled oraffixed to the rear surface of the light or lamp (e.g., by screws,clips, or adhesive). When the object mount 104 is coupled to a light orlamp, the object mount 104 can be considered a light mount. In someembodiments, the light mount or features thereof can be incorporated ordefined as part of the rear or side surface of the light or lamp.

When the mountable object 502 is a light or lamp as shown in FIGS. 6Aand 6B, the wall mount 102 and the light or lamp having the light mountcoupled thereto can be considered part of a mountable lighting system.As shown in FIGS. 6A and 6B, the light or lamp can have an electricalcord extending from the light or lamp. In these and other embodiments,the mountable lighting system can comprise a light switch electricallycoupled to or in electrical communication with the mountable light orlamp. In additional embodiments, the light or lamp can be powered by oneor more batteries or be electrically coupled to or in electricalcommunication with wires from an AC power supply such as a mains powerof a residential or commercial building. In these embodiments, themountable lighting system comprising a light or lamp mounted by themounting bracket assembly 100 can replace expensive and difficult toinstall flush-mount lighting fixtures.

FIG. 6C illustrates that the mountable object 502 can be a board orframe that can be mounted to a wall or another mounting surface by themounting bracket assembly 100. For example, the board can be awhiteboard, blackboard, a dry-erase board, a corkboard, a tack board, amagnetic board, a picture board, or a combination thereof. The frame canbe a picture frame, a painting frame, a poster frame, a document frame,or a combination thereof. The board or frame can each have a rearsurface comprising a depression or divot defined along the rear surface.The depression or divot can be positioned or defined in proximity to theobject mount 104 coupled or affixed to the rear surface of the board orframe (e.g., by screws, clips, or adhesive). In some embodiments, theobject mount 104 or features thereof can be incorporated or defined aspart of the rear surface of the board or frame.

FIG. 6D illustrates that the mountable object 502 can be a vase or othertype of container that can be mounted to a wall or another mountingsurface by the mounting bracket assembly 100. For example, the vase canbe a plant vase (e.g., a flower vase), a decorative vase, or acombination thereof. The container can be any type of container forstoring or housing an object. The vase or container can each have a rearsurface comprising a depression or divot defined along the rear surface.The depression or divot can be positioned or defined in proximity to theobject mount 104 coupled or affixed to the rear surface of the vase orcontainer (e.g., by screws, clips, or adhesive). In some embodiments,the object mount 104 or features thereof can be incorporated or definedas part of the rear surface of the vase or container.

Each of the individual variations or embodiments described andillustrated herein has discrete components and features which may bereadily separated from or combined with the features of any of the othervariations or embodiments. Modifications may be made to adapt aparticular situation, material, composition of matter, process, processact(s) or step(s) to the objective(s), spirit or scope of the presentinvention.

Methods recited herein may be carried out in any order of the recitedevents that is logically possible, as well as the recited order ofevents. Moreover, additional steps or operations may be provided orsteps or operations may be eliminated to achieve the desired result.

Furthermore, where a range of values is provided, every interveningvalue between the upper and lower limit of that range and any otherstated or intervening value in that stated range is encompassed withinthe invention. Also, any optional feature of the inventive variationsdescribed may be set forth and claimed independently, or in combinationwith any one or more of the features described herein. For example, adescription of a range from 1 to 5 should be considered to havedisclosed subranges such as from 1 to 3, from 1 to 4, from 2 to 4, from2 to 5, from 3 to 5, etc. as well as individual numbers within thatrange, for example 1.5, 2.5, etc. and any whole or partial incrementstherebetween.

All existing subject matter mentioned herein (e.g., publications,patents, patent applications) is incorporated by reference herein in itsentirety except insofar as the subject matter may conflict with that ofthe present invention (in which case what is present herein shallprevail). The referenced items are provided solely for their disclosureprior to the filing date of the present application. Nothing herein isto be construed as an admission that the present invention is notentitled to antedate such material by virtue of prior invention.

Reference to a singular item, includes the possibility that there areplural of the same items present. More specifically, as used herein andin the appended claims, the singular forms “a,” “an,” “said” and “the”include plural referents unless the context clearly dictates otherwise.It is further noted that the claims may be drafted to exclude anyoptional element. As such, this statement is intended to serve asantecedent basis for use of such exclusive terminology as “solely,”“only” and the like in connection with the recitation of claim elements,or use of a “negative” limitation. Unless defined otherwise, alltechnical and scientific terms used herein have the same meaning ascommonly understood by one of ordinary skill in the art to which thisinvention belongs.

In understanding the scope of the present disclosure, the term“comprising” and its derivatives, as used herein, are intended to beopen-ended terms that specify the presence of the stated features,elements, components, groups, integers, and/or steps, but do not excludethe presence of other unstated features, elements, components, groups,integers and/or steps.

The foregoing also applies to words having similar meanings such as theterms, “including”, “having” and their derivatives. Also, the terms“part,” “section,” “portion,” “member” “element,” or “component” whenused in the singular can have the dual meaning of a single part or aplurality of parts. As used herein, the following directional terms“forward, rearward, above, downward, vertical, horizontal, below,transverse, laterally, and vertically” as well as any other similardirectional terms refer to those positions of a device or piece ofequipment or those directions of the device or piece of equipment beingtranslated or moved. Finally, terms of degree such as “substantially”,“about” and “approximately” as used herein mean a reasonable amount ofdeviation (e.g., a deviation of up to ±0.1%, ±1%, ±5%, or ±10%, as suchvariations are appropriate) from the specified value such that the endresult is not significantly or materially changed.

This disclosure is not intended to be limited to the scope of theparticular forms set forth, but is intended to cover alternatives,modifications, and equivalents of the variations or embodimentsdescribed herein. Further, the scope of the disclosure fully encompassesother variations or embodiments that may become obvious to those skilledin the art in view of this disclosure.

1. A mounting bracket assembly, comprising: a wall mount configured tobe mounted to a wall, wherein the wall mount is obround-shaped andcomprises a raised internal ridge extending from a wall-facing side ofthe wall mount and a rim segment surrounding the raised internal ridge,wherein a clearance space is formed in between the wall and the rimsegment when the wall mount is mounted to the wall; and an object mountconfigured to be coupled to a surface of a mountable object, wherein theobject mount comprises a curved ledge and an inwardly-projecting brim,wherein at least part of the curved ledge rests on a top of the wallmount and the inwardly-projecting brim is positioned within part of theclearance space when the mountable object is mounted to the wall.
 2. Themounting bracket assembly of claim 1, wherein the curved ledge issubstantially shaped as an arch.
 3. The mounting bracket assembly ofclaim 1, wherein the curved ledge is part of an upside down U-shapedprotrusion extending from an object-facing surface of the object mount,and wherein at least part of the upside down U-shaped protrusion isconfigured to be slid on to the top of the wall mount when the wallmount is mounted to the wall in order to mount the mountable object tothe wall via the mounting bracket assembly.
 4. The mounting bracketassembly of claim 3, wherein the upside down U-shaped protrusionterminates at two protrusion ends, wherein the two protrusion ends flarelaterally outward such that a distance separating the two protrusionends is greater than a ledge width of the curved ledge, wherein theflared protrusion ends are configured to allow a user to level themountable object when the mountable object is mounted to the wall viathe mounting bracket assembly.
 5. The mounting bracket assembly of claim4, wherein the upside down U-shaped protrusion comprises a protrusionfront surface, and wherein the protrusion front surface is configured tocontact the surface of the mountable object when the object mount iscoupled to the mountable object.
 6. The mounting bracket assembly ofclaim 1, wherein the rim segment is obround-shaped and wherein at leastpart of the inwardly-projecting brim of the object mount is shaped as anupside down U.
 7. The mounting bracket assembly of claim 1, wherein theraised internal ridge of the wall mount has a ridge height, wherein therim segment of the wall mount has a rim height, and wherein the ridgeheight is greater than the rim height.
 8. The mounting bracket assemblyof claim 7, wherein the curved ledge of the object mount has a ledgeheight, wherein the ledge height is substantially equal to the rimheight of the rim segment.
 9. The mounting bracket assembly of claim 1,wherein the wall mount has a wall mount length and a wall mount width,wherein the wall mount further comprises a singular mounting holepositioned substantially in a center of the wall mount such that thesingular mounting hole is positioned substantially at a midpoint alongboth the wall mount length and the wall mount width, and wherein thewall mount is mounted to a wall via one mounting screw extending throughthe singular mounting hole.
 10. The mounting bracket assembly of claim1, wherein the object mount comprises two object mount holes positionedlaterally outward of the upside down U-shaped protrusion, and whereinthe object mount is coupled to the surface of the mountable object bytwo object mounting screws extending through the two object mount holes.11. A method of mounting an object to a wall, comprising: mounting awall mount to the wall, wherein the wall mount is obround-shaped andcomprises a raised internal ridge extending from a wall-facing side ofthe wall mount and a rim segment surrounding the raised internal ridge,wherein a clearance space is formed in between the wall and the rimsegment when the wall mount is mounted to the wall; and sliding amountable object comprising an object mount coupled to a surface of themountable object on to a top of the wall mount to mount the mountableobject to the wall, wherein the object mount comprises a curved ledgeand an inwardly-projecting brim, wherein at least part of the curvedledge rests on the top of the wall mount and the inwardly-projectingbrim is positioned within part of the clearance space when the mountableobject is mounted to the wall.
 12. The method of claim 11, wherein thecurved ledge is substantially shaped as an arch, wherein the rim segmentis obround-shaped, and wherein at least part of the inwardly-projectingbrim of the object mount is shaped as an upside down U.
 13. The methodof claim 11, wherein sliding the mountable object on to the top of thewall mount further comprises sliding at least part of an upside downU-shaped protrusion extending from an object-facing surface of theobject mount on to the top of the wall mount.
 14. The method of claim11, further comprising leveling the mountable object by adjusting themountable object clockwise or counterclockwise when the mountable objectis mounted to the wall, wherein the upside down U-shaped protrusionterminates at two protrusion ends, wherein the two protrusion ends flarelaterally outward such that a distance separating the two protrusionends is greater than a ledge width of the curved ledge, and wherein theflared protrusion ends are configured to allow a user to level themountable object.
 15. The method of claim 11, wherein the raisedinternal ridge of the wall mount has a ridge height, wherein the rimsegment of the wall mount has a rim height, and wherein the ridge heightis greater than the rim height.
 16. The method of claim 11, whereinmounting the wall mount to the wall further comprises screwing onemounting screw into the wall through a singular mounting hole defined inthe center of the wall mount, wherein the singular mounting hole ispositioned substantially at a midpoint along both a wall mount lengthand a wall mount width of the wall mount.
 17. A mountable lightingsystem, comprising: a wall mount configured to be mounted to a wall,wherein the wall mount is obround-shaped and comprises a raised internalridge extending from a wall-facing side of the wall mount and a rimsegment surrounding the raised internal ridge, wherein a clearance spaceis formed in between the wall and the rim segment when the wall mount ismounted to the wall; a light comprising a light surface; and a lightmount coupled to or integrated with the light surface, wherein the lightmount comprises a curved ledge and an inwardly-projecting brim, whereinat least part of the curved ledge rests on a top of the wall mount andthe inwardly-projecting brim is positioned within part of the clearancespace when the light is mounted to the wall.
 18. The mountable lightingsystem of claim 17, wherein the light surface comprises a depression ordivot defined along the light surface in proximity to the light mount.19. The mountable lighting system of claim 17, wherein the curved ledgeis part of an upside down U-shaped protrusion extending from alight-facing surface of the light mount, and wherein at least part ofthe upside down U-shaped protrusion is configured to be slid on to thetop of the wall mount when the wall mount is mounted to the wall inorder to mount the light to the wall.
 20. The mountable lighting systemof claim 17, wherein the curved ledge is substantially shaped as anarch, wherein the rim segment is obround-shaped, and wherein at leastpart of the inwardly-projecting brim of the light mount is shaped as anupside down U.